Introduction to Licensed Exempt Wireless Networking

1. Introduction to Licensed Exempt Wireless Networking Tim Pozar Late Night Software www.lns.com Bay Area Wireless Users Group www.bawug.org

2. The Lofty Goals... • A general knowledge of 802.11 and the licensed exempt spectrum. • “10,000 foot view” as details can't be covered in 1 hour. • Would need at least a 3 day course

3. Applications • Home/Office (LAN) • Originally designed for and the traditional use. • Campus Area Network (CAN) • How do you get across the street or a city? • Wireless ISPs (WISPs) • WISPs will try to cover a small area (Hot Spot) such as a store or cafe all the way up to a rural or metropolitan area (MAN). • One Access Point (AP) can do about an 8 mile radius legally.

4. Why Use 802.11? • Biggest reason: Non-licensed • Significantly less regulatory control • No expensive licenses or coordination. • The arcane regulatory knowledge needed for licensed radios is not needed. • The hardware cost is magnitudes less than equivalent licensed technology. • Client cards are from $35 to $150; Access Points are from $50 to $500. • Even less than (non) unlicensed "carrier class" radios • Example: Western Multiplex/Proxim Tsunami point-to-point radios are $12,000 per end not including the thousands of $ for antennas, coax, installation, etc.

5. Why Use 802.11? (cont.) • Speeds range from 11Mb/s to 54Mb/s • Another magnitude jump of low-cost networking hardware from a couple of years ago. (2Mb/s) or even 2 to 3 magnitudes of amateur packet radio (1.2-56Kb/s). • Real world speeds about 5Mb/s to 20Mb/s • Plug and play • Most modern operating systems support 802.11 • i.e. Mac OSX, *BSD, Linux, MS-Win 95 and up. • Depending on implementation, it can be as easy to set up as standard Ethernet and in some cases easier.

6. Why Use 802.11? (cont.) • A significant number of manufactures are putting money and releasing hardware that are compatible with 802.11 standards. • Cisco, Agere, Breezecom, Symbol/3com, Xircom/Intel, Intersil/Prism, Atheros, Proxim/ORiNOCO, etc. • Of course its wireless • Good solution for older installations/buildings • Roaming of laptops

7. Why Not Use 802.11? • Biggest reason: Non-licensed • Non-existent coordination facilities. • Other users on the bands. • Folks with large organizations that lobby (ie. ARRL, Society of Broadcast Engineers) • “Regulations Affecting 802.11 Deployment”: http://www.lns.com/papers/part15 • You have no legal priority or recourse over any other user of the spectrum...

8. FCC R&R Part 15.5General Conditions of Operation (b) Operation of an intentional, unintentional, or incidental radiator is subject to the conditions that no harmful interference is caused and that interference must be accepted that may be caused by the operation of an authorized radio station, by another intentional or unintentional radiator, by industrial, scientific and medical (ISM) equipment, or by an incidental radiator. (c) The operator of a radio frequency device shall be required to cease operating the device upon notification by a Commission representative that the device is causing harmful interference. Operation shall not resume until the condition causing the harmful interference has been corrected.

9. Why Not Use 802.11? (cont.) • The protocols have problems scaling. • Companies like Etherlinks are trying to solve it. • Modifications to the standards will help minimize interference (ie. Automatic Power Control and frequency selection) • Outdoor deployment requires RF engineering knowledge to minimize interference issues. • Other regulatory issues one may have to deal with for outdoor deployment. • Radio Frequency Radiation standards • Local ordinances for antennas • Security – (more later on)

10. Conclusions on issues • Building an expensive network on 802.11 can be risky as you have no rights or priorities. • Coordinate with other users. • A properly designed network will survive longer. • Other issues can affect you like FCC Rules changes or pressure to get the FCC to enforce. Be active in watching and changing the FCC's Rules!

11. How does the city and public benefit?

12. Neighborly thing to do. Community networks help get people into their neighborhoods to meet each other and help each other participate. That's ultimately good for the city.

13. Digital Divide Extends the efforts of a city or community to provide Internet access. Much beyond attempts such as the terminals in the libraries. I.e. Some areas in San Francisco do not have access to DSL as they are in an area that isn't served or are too far away from the Central Office. With the downturn in the economy, this problem will likely not be rectified in the near future by commercial interests. Even if they can access the Internet, at $50 a month some folks will see food and rent as more of a priority over network access.

14. Public Safety Fast Network – Over the 19.2Kb/s of the current system. 802.11 can be 570 times faster. Parallel infrastructure is ideal for backup (or concurrent) emergency communications. Common Intra and Interdepartmental network. Can be utilized in extreme emergency conditions such as the '89 earthquake. Neighbour Emergency Response Team (NERT) Everyday applications: Building and Fire inspection via Tablet PCs

15. Competition A city-wide community network promotes business and competition, as anyone can participate and offer services. Much like Palo Alto's fiber ring.

16. Could keep other providers competitive The latest FCC ruling that feds do not regulate the copper for the last mile. This could be the death knell for competition for DSL providers.

17. Increases City and Business Revenue Encourages commerce as tourist and business visitors will likely stay (and shop) in a city if a public network is there. Also encourages park use and benefits businesses surrounding the parks.

18. Experimentation Test Bed Test bed for experimentation for public and commercial use. Feeding public access content to cable access channels. Art pieces. Provides better access to the community for news reporting. Via photo bloging. BBC news asking for images from clients.

19. Topology - Star Mode • Traditional Design • One AP / Many clients • Hidden Xmitter Problems

20. Topology - Bridging • Used to link two Ethernet Segments • If designed properly it can go 10s of miles. • Traffic is unencrypted unless you run additional software or hardware.

21. Topology - Repeater • Extends the wireless range. • Getting around obstacles

22. Access Points – Examples... • Range in costs from $50 to $1000 • High end to low: • Cisco 1200 • Supports 802.11b, 802.11a & 802.11g • Space for 2,048 MAC addresses • ~$600 to $800 • Cisco 350 • Next step in the “Aironet” line from the 340 series. • ~$500 to $1000 • Space for 2,048 MAC addresses

23. APs – Mid-level $ • Apple Airport 2 • MAC support for 50 users • Router supports NAT • Modem for out & inbound PPP • 15dBm (30mW) TPO • ~$300

24. APs – Low End $ • D-Link AirPlus Enhanced 2.4GHz Wireless Router • ~$50 to $100 (Some $50 rebates out there) • Proprietary 22Mb/s protocol using Packet Binary Convolutional Coding (PBCC) – Not accepted by the 802.11g working group. • 256bit WEP

25. Home-brew APs - Example • Soekris 4521 - www.soekris.com • 2 PCMCIA slots and 1 mini-PCI for radios (3 radios total) • 133MHz – 486 • 2 100base-T • CompactFlash slot • FreeBSD 4.7 in < 32 MB • IPFW, NAT, NoCat, Open1X (open1x.org), etc.

26. BAWRN Designed Hardware • Layer 2/3 switching/routing between radios via 802.11 and cat-5. • Layer 2/3 to access points • Can run “fancy” routing protocols such as spanning tree or BGP. • Can also be its own AP.

27. Other Hardware • Amplifiers • Great for TX and RX issues if used properly. • Best installed next to the antenna to overcome cable loss. • Can cause more “RF pollution” with excessive power. • Regulation issues – Equipment Certification. • Cables • Bigger (fatter) the better for longer runs. • Lower loss cables like the LMR-600 • Grounding and Lighting Arrestors • You don't want to keep replacing your gear do you? • Battery Backup • How critical is it if the power goes out?

28. Security and Authentication • Typically, 802.11 radios do not have either • Security • All the normal security issues and more. • Vendor defaults to open. • The current “security” (WEP), is badly implemented • Want to crack WEP? AirSnort – airsnort.shmoo.com • May take up to a week to discover the key. • WEP key discovery is passive. • Only authorizes the clients to the AP. Does not authorize the AP to the clients. No mutual authorization. • Attackers don't have to be physically connected. • So long as they can hear the AP and the AP can hear them.

29. Security Needs • Determine what the real threat is. • What are your security policies and incident response procedures? • Terms of service for open and semi-open APs • Access Monitoring and Accounting • Who is logging in and what are they doing? • Firewalling • Minimizing attacks • Preventing access to “internal” resources • ie. Account lists, AP software • Resource Allocation • ie. Bandwidth hogs

30. Community Networks • The ones that are stretching the limits of the technology. • Uses much of the same technology and layout. • Just more power and slightly more expense. • Co-operative in nature • Defined to be “free” within a network co-op. • Examples: • Neighborhood Area Networks (NAN) and Hot-Spots • Early example of a community network • Short range - ~1 mile diameter • NYC Wireless - Bryant Park in NYC... • Coverage Map of PozarLAN...

31. Bryant Park

33. Community Networks • Metropolitan Area Network (MAN) sized: • San Francisco Presidio – SFLAN • Point to multipoint • Seattle Wireless... • Mesh Network • Multiple Counties: • BARWN – San Francisco Bay Area...

34. Seattle Wireless Nodes

35. BAWRN Network Map

36. Future... • 802.11e – MAC layer QoS • It should be out soon. • 802.11f – Inter-Access Point Protocol (IAPP) • Roaming between all access points. • Troubles getting vendors to agree. • 802.11g – 54Mb/s (really 22Mb/s) at 2.4GHz • Hardware is shipping while the standard was just approved. There may be some incompatibility. • 802.11H – Spectrum Managed 802.11a • Automatic power control • Automatic frequency selection • Needed for EU and something 802.11b should have.

37. Future (cont.) • 802.11i – Security • WEP2 out first • New hardware needed • How do we increase bandwidth while still addressing the physics (turf and spectrum)? Possible Solutions are: • Mesh • MeshNetworks, et. al. • Phased-Array Antennas • Vivato, et. al.

38. Resources • Books • “Building Wireless Community Networks” - Rob Flickenger – O'Reilly • “802.11 Wireless Networks” - Matthew Gast – O'Reilly • http://www.freenetworks.org • The “meta” site for the community groups such as: • Bay Area Wireless Users Group - http://www.bawug.org • Great mailing list. • http://nocat.net • AAA open-software for *NIX • http://www.ieee.org • The standards body for 802.(n)(x)

39. Thank You and Q&A • Bay Area Wireless Users Group: www.bawug.org • Bay Area Research Wireless Network: www.barwn.org • Tim Pozar: pozar@lns.com